One of the fascinating features of

One of the fascinating features of Ag nanocrystals is the tunable localized surface plasmon resonance (LSPR) fromthe visible to near infra-red (NIR) regime by controlling the crystal size and shape [2].Therefore, Ag nanostructures are one of the most commonly used materials for SERS, optical sensing, and cell imaging [2]. In addition,it was found that Ag, particularly in the form of NPs, can be used as catalysts in various oxidation and oxidative coupling reactions [6].
Besides Au nanostructures which have been successfully incorporated with graphene, graphene-templated Ag nanomaterials have also been synthesized and used for many applications in SERS, optical sensors and catalysis [22,63–78]. In the synthesis of graphene–Ag composites, AgNO3 is the most commonly used precursor which can be easily reduced in the presence of reducing agents such as amines, NaBH4, and ascorbic acid [22,63–68]. For example, Ag NPs adsorbed on graphene was realized by using an electrostatic force directed assembly technique at room temperature [64]. However, our group demonstrated that Ag NPs could grow on the GO or rGO surface by simply heating the single-layer GO or rGO nanosheets, which were immobilized on a 3 aminopropyltriethoxysilane (APTES)-modified-Si/SiO2 substrate, in a AgNO3 aqueous solution at 75 8C without using any reducing agent (Fig. 4a) [22]. Alternatively, graphene-templated Ag NPs can also be obtained by other synthetic approaches such as photochemical reduction, substrateinduced galvanic reaction and thermal evaporation [65–78]. As an interesting example, well-defined gauze-like GO nanosheets enwrapping Ag/AgX (X = Br, Cl) NPs were facilely prepared by adding an aqueous solution of GO and AgNO3 to a surfactant solution of cetyltrimethylammonium bromide (CTAB) or cetyltrimethylammonium chloride (CTAC) in chloroform (Fig. 4b) [69]. The obtained GO/Ag/AgX hybrid materials were highly efficient in harvesting visible light through plasmonic
excitation.